Abstract
GABA gating an anion channel primarily permeable to chloride can hyperpolarize or depolarize, depending on whether the chloride equilibrium potential (ECl) is negative or positive, respectively, to the resting membrane potential (Erest). If the transmembrane Cl− gradient is set by active transport, those neurons or neuronal regions that exhibit opposite responses to GABA should express different chloride transporters. To test this, we immunostained retina for the K-Cl cotransporter (KCC2) that normally extrudes chloride and for the Na-K-Cl cotransporter (NKCC) that normally accumulates chloride. KCC2 was expressed wherever ECl is either known or predicted to be negative to Erest (ganglion cells, bipolar axons, and OFF bipolar dendrites), whereas NKCC was expressed wherever ECl is either known or predicted to be positive to Erest(horizontal cells and ON bipolar dendrites). Thus, in the retina, the opposite effects of GABA on different cell types and on different cellular regions are probably primarily determined by the differential targeting of these two chloride transporters.
Bipolar cells in vertebrate retina comprise two classes: OFF and ON, so termed because light stimuli drive their membrane potentials in opposite directions. When light decrement on the receptive field center enhances glutamate release from photoreceptors onto bipolar dendritic tips, OFF cells depolarize and ON cells hyperpolarize. When light decrement on the receptive field surround increases GABA release from horizontal cells onto bipolar dendrites (Schwartz, 1982), OFF cells hyperpolarize and ON cells depolarize (Werblin and Dowling, 1969; Kaneko, 1970; Ayoub and Lam, 1984). Because the dendrites of both bipolar classes express GABAA/C receptors (Chappell et al., 1992;Greferath et al., 1994; Vardi and Sterling, 1994; Enz et al., 1996;Koulen et al., 1998; Shields et al., 2000), one may reasonably infer that GABA contributes to both responses.
How glutamate evokes opposite responses is known; OFF cells depolarize via an ionotropic glutamate receptor that opens a cation channel, whereas ON cells hyperpolarize via a metabotropic glutamate receptor (mGluR6) that closes a cation channel (Nawy and Jahr, 1990;Shiells and Falk, 1990; Yamashita and Wässle, 1991a; de la Villa et al., 1995). However, how GABA might evoke opposite responses for the surround has been a mystery. Both bipolar classes express ionotropic GABA receptors that open a chloride channel, so opposite responses to GABA cannot arise from different gating properties of the receptor.
GABA would evoke opposite responses if chloride equilibrium potential (ECl) in the two bipolar classes were on opposite sides of the resting potential (Erest) (Vardi and Sterling, 1994). Thus, GABA would hyperpolarize an OFF cell if ECl were negative to the resting potential and would depolarize an ON cell if ECl were positive to the resting potential. Indeed, ECl was positive when measured by chloride electrode in ON cells of the intact mudpuppy retina (Miller and Dacheux, 1983). However, ECl was always negative when assessed by measuring the GABA reversal potential in somas of isolated mammalian bipolar cells (Suzuki et al., 1990; Yamashita and Wässle, 1991b). Possibly a negative ECl in the bipolar axon terminals, which all intensely express ligand-gated anion channels (GABAA, GABAC, and glycine receptor), dominates these compact neurons (only 50 μm between dendritic and axonal tips). If so, possible differences in ECl between dendritic and axonal compartments could not be resolved by somal recordings.
ECl depends on intracellular chloride concentration, which appears to be regulated primarily by two transporters, an Na-K-Cl cotransporter (NKCC) that normally accumulates chloride and a K-Cl cotransporter (KCC) that normally extrudes chloride (for review, see Russell, 2000). Certain neurons and epithelial cells with ECl positive to the resting potential express NKCC, whereas neurons with an EClnegative to the resting potential express KCC2 (the neuron-specific isoform). Accordingly, if NKCC and KCC2 are the primary Cl− transporters in bipolar cells, we predicted that OFF dendrites should express KCC2 and ON dendrites should express NKCC. Here, we confirm this prediction by confocal and electron microscopy. We also show that NKCC and KCC2 are polarized at opposite poles of the same neuron (rod ON bipolar cell). This suggests that GABA depolarizes the cell at one end (dendrite) and hyperpolarizes at the other (axon terminal).
MATRIALS AND METHODS
Immunoblots
Membranes were prepared from freshly dissected tissue using differential centrifugation. Briefly, tissue was homogenized in 1–40 ml of homogenization buffer (in mm: 250 sucrose, 10 Tris, 10 HEPES, and 1 EDTA, pH adjusted to 7.2 at 24°C) containing protease inhibitors. After 10 strokes in a glass Teflon homogenizer, the homogenate was centrifuged at 7000 rpm for 10 min at 4°C (Sorval RC5, SS-34 rotor). The supernatant was centrifuged at 20,000 rpm for 30 min at 4°C. The final pellet was resuspended in ∼100–500 μl of homogenization buffer with protease inhibitors and stored at −80°C. Protein concentration was determined using a Micro-BCA protein kit (Pierce, Rockford, IL). Membrane proteins were resolved by SDS-PAGE using a 7.5% Tricine gel system. Gels were electrophoretically transferred from unstained gels to polyvinylidene difluoride (PVDF) membranes (Immobilon P; Millipore, Bedford, MA) in transfer buffer (192 mm glycine, 25 mm Tris-Cl, pH 8.3, and 15% methanol) for 5 hr at 50 V using a Bio-Rad (Hercules, CA) Trans-Blot tank apparatus. PVDF-bound protein was visualized by staining with Coomassie brilliant blue R-250. The PVDF membrane was blocked in PBS–milk (7% nonfat dry milk and 0.1% Tween 20 in PBS, pH 7.4) for 1 hr and then incubated in PBS–milk with an anti-NKCC monoclonal antibody (T4) (Lytle et al., 1995) or affinity-purified anti-KCC2 polyclonal antibodies (Williams et al., 1999) for 2 hr at 24°C. After three 10 min washes in PBS–milk, the PVDF membrane was incubated with secondary antibody [horseradish peroxidase (HRP)-conjugated goat anti-mouse IgG; Amersham Pharmacia Biotech, Arlington Heights, IL] for 2 hr at 24°C in PBS–milk. After three washes in PBS–0.1%Tween 20, bound antibody was detected using an enhanced chemiluminescence assay (NEN, Boston, MA).
Immunocytochemistry
Eye cups from adult rhesus monkey (obtained from Covance Research Products Inc., Alice, TX) were fixed for 1 hr in 4% paraformaldehyde diluted in 0.1 m phosphate buffer at pH 7.4. Eyes from adult rat, mouse, guinea pig, or rabbit were removed under deep anesthesia [for rat and rabbit, pentobarbital (45 μg/gm); for mouse, mixture of ketamine (85 μg/gm) and xylazine(13 μg/gm); and for guinea pig, ketamine (40 μg/gm), xylazine (8 μg/gm), and pentobarbital (35 μg/gm)]. Anesthesia was injected intraperitoneally. Animals were killed by anesthetic overdose (three times the initial doses). Animals were treated in compliance with federal regulations and University of Pennsylvania policy. For most experiments, rodent retinas were fixed in buffered 4% paraformaldehyde containing 0.01% glutaraldehyde for 1 hr at room temperature.
Light microscopy. Tissue was cryoprotected with 30% sucrose in phosphate buffer (overnight), frozen in a mixture of Tissue Freezing Medium (Electron Microscopy Sciences, Ft. Washington, PA) and 20% sucrose (1:2), and cryosectioned vertically at 10 μm. Sections were then stained according to a standard protocol: soak in diluent containing 0.1 m phosphate buffer, 10% normal goat serum, 5% sucrose, and 0.3% Triton X-100; incubate in primary antibody overnight at 4°C (anti-KCC2, 1:200–1000; anti-NKCC, 1:3000); wash and incubate 3 hr in a secondary antibody conjugated to fluorescent marker or HRP. Sections with fluorescent markers were mounted in Vectashield (Vector Laboratories, Burlingame, CA). Sections with HRP markers were reacted with H2O2 plus 3, 3′-diaminobenzidine tetrahydrochloride (DAB) and mounted in glycerol. Sections were visualized with a confocal microscope (Leica, Nussloch, Germany).
Double-labeling. Sections were incubated simultaneously in two primary antibodies, one a marker (raised in mouse or rabbit) and the other a transporter, anti-KCC2 (raised in rabbit) or anti-NKCC (raised in mouse). Sections were then incubated simultaneously in two secondary antibodies, an F(ab)2 fragment conjugated to fluorescein isothiocyanate (FITC) and another F(ab)2 fragment conjugated to lisamine rhodamine. Double-labeling for parvalbumin and NKCC (both raised in mouse) was done by incubating sections sequentially as follows: anti-NKCC, rinse, anti-mouse F(ab) fragments conjugated to Cy3, rinse, anti-parvalbumin, rinse, and anti-mouse IgG conjugated to FITC. Control experiments in which anti-parvalbumin was omitted had no FITC stain.
Electron microscopy. Fixative was 4% paraformaldehyde and 0.01% glutaraldehyde in 0.12 m phosphate buffer. After cryoprotection, eyecups were freeze-thawed three times, embedded in 4% agarose, and vibratome sectioned at 100 μm. Sections were processed as for light microscopy, but Triton X-100 was omitted or used at 0.1% for only 30 min at room temperature. Incubation in primary antibody was extended to 2–3 d. DAB reaction product was silver-intensified and then gold-substituted (modified from van den Pol, 1988; Johnson and Vardi, 1998). The tissue was then osmicated (2% osmium tetroxide, 60 min), stained with 1% uranyl acetate in 70% ethanol (60 min), dehydrated in ethanol, soaked in propylene oxide, and embedded in Epon 812. Ultrathin sections were mounted on Formvar-coated slot grids and counterstained with heavy metals.
Antibodies. The antibodies used are as follows: anti-KCC2, a polyclonal antibody raised in rabbit against a 112 amino acid sequence of the C terminus of rat KCC2; anti-NKCC (clone T4), a mouse monoclonal that recognizes all known isoforms (Lytle et al., 1995); anti-parvalbumin, mouse monoclonal (Sigma, St. Louis, MO); and anti-protein kinase C (PKC), mouse monoclonal (Amersham Pharmacia Biotech). For several antigens, we used two different antibodies, one raised in rabbit for double-labeling with anti-NKCC and the other raised in mouse for double-labeling with anti-KCC2. These were as follows: anti-human mGluR6, a polyclonal antibody raised in rabbit and in mouse against the C terminus (Vardi et al., 2000); anti-Gαo, a polyclonal raised in rabbit against the C terminus (gift of Dr. D. Manning, University of Pennsylvania), and a mouse monoclonal against the purified bovine protein (MAB 3071; Chemicon) (Li et al., 1995); and anti-calbindin-D (28 kDa), a monoclonal (clone CL-300; Sigma) and a polyclonal (Swant). Secondary antibodies conjugated to fluorescent markers were from Jackson ImmunoResearch (West Grove, PA), and those conjugated to HRP were from Protos Immunoresearch (San Francisco, CA).
RESULTS
Both cation chloride cotransporters are expressed in retina
The membrane fractions of retina and brain (mouse, rat, and rabbit) were probed by SDS-PAGE Western blots with antibodies to both cation chloride cotransporters NKCC and KCC2. In all tissues, NKCC was detected as a band at ∼160 kDa and KCC2 as a band at ∼140 kDa (Fig.1). Each band corresponded to the predicted molecular weight of the transporter. Expression levels were similar in retina and brain. Thus, both transporters are expressed abundantly in retina.
The two transporters distribute differently across retinal layers
In the outer plexiform layer (OPL), antibodies to both transporters stained strongly but quite differently (Fig.2). Anti-NKCC stained throughout the layer, being punctate in the outer half and diffuse in the inner half. Anti-KCC2 stained primarily the middle stratum, distributing in a punctate manner in short rows beneath the cone pedicles. This pattern resembled staining for ligand-gated chloride channels (GABAA receptor) (Vardi et al., 1992; Vardi and Sterling, 1994). Staining the same section with both antibodies showed that the two cotransporters do not colocalize (Fig.3, middle column,bottom).
In the inner nuclear layer (INL), NKCC staining was negative, but anti-KCC2 stained somas of the upper two tiers. In the inner plexiform layer (IPL), NKCC staining was negative or weak, and anti-KCC2 stained strongly in a punctate manner, distributing evenly across the layer except for a negative band in the middle strata. In the ganglion cell layer, NKCC staining was negative in the ganglion cell somas but positive in the axons, whereas KCC2 staining was positive in ganglion cell somas and dendrites but negative in the axons.
Anti-KCC2 applied to rat, rabbit, and monkey retina gave similar results. Staining was reduced or completely abolished in monkey retina when the antibody was preabsorbed with its immunogenic peptide (1–10 μg/ml). Because the anti-NKCC antibody was monoclonal (and thus recognized a single epitope), preabsorption would not test specificity. Therefore, we tested specificity by applying the antibody against a wider range of species (mouse, rat, rabbit, guinea pig, cat, baboon, and macaque), always with similar results in the outer plexiform layer. However, in rodent retina, ganglion cell somas and their axons did stain for NKCC. We conclude that the highly conserved staining patterns of both antibodies represent the true localization of the transporters. The next step was to determine which cell types expressed the transporters, and we did this by comparing their staining patterns with those of established markers.
The two transporters are expressed differently by dendrites of ON and OFF bipolar cells
The dendritic tips of ON bipolar cells were identified by their expression of mGluR6 (Vardi et al., 2000) and Gαo (Vardi, 1998). The cone bipolar tips can be recognized because they end in the middle stratum of the outer plexiform layer where they invaginate the cone pedicles. The rod bipolar dendritic tips end higher where they invaginate the rod spherules. Having marked the ON bipolar tips with anti-mGluR6 or anti-Gαo, we applied anti-NKCC. NKCC sharply colocalized with mGluR6 (Fig. 3,left column) and with the tips of Gαo-stained dendrites. It did not localize with ON dendritic shafts (Fig. 3, middle column, top). Electron microscopy confirmed that dendritic tips of rod bipolar cells and ON cone bipolar cells were stained for NKCC (Fig. 3, right column). Thus, both types of ON bipolar (rod and cone) sharply localize NKCC to the tips of their dendrites. These dendrites did not express KCC2 because double-staining for either mGluR6 and KCC2 (Fig. 3, middle column,middle) or both transporters did not colocalize (Fig. 3,middle column, bottom).
The tips of OFF cone bipolar occupy the stratum just beneath the cone terminals. This stratum was stained when we applied anti-KCC2. To determine whether the stained processes in this stratum were OFF bipolar dendrites, we examined tissue by electron microscopy (Fig.4, left). In monkey peripheral retina, stained dendrites formed basal contacts corresponding to the sites of OFF bipolar cells (Dowling and Boycott, 1966; Kolb and Nelson, 1995; Calkins et al., 1996; Chun et al., 1996). We also used anti-calbindin to stain a type of OFF bipolar cell (DB3) (Grünert et al., 1994). This type expressed KCC2 strongly in soma and dendrites (Fig. 4) but also in the axon terminal. Thus, OFF cone bipolar cells express KCC2 and localize it to their dendritic tips.
The two transporters distribute to opposite poles of an ON bipolar cell
ON bipolar cells raise a special problem because they express ligand-gated anion channels both on their dendrites in which GABA presumably depolarizes and also on their axon terminals in which GABA hyperpolarizes (Tachibana and Kaneko, 1984, 1987) (for review, seeFreed, 1992). Having shown that NKCC is present in ON dendritic tips, but not in the axon terminals (Figs. 2, 3), we wondered whether ON axon terminals might express KCC2. To test this, we identified the soma and axon terminal of an ON cell (rod bipolar) with antibody to PKC (Negishi et al., 1988). Anti-KCC2 weakly stained the rod bipolar soma but strongly stained the axon terminal (monkey and rabbit), localizing to the plasma membrane (Fig. 5). Thus, an ON rod bipolar cell targets NKCC to the dendrite and KCC2 to the axon. This supports the idea that GABA depolarizes the dendrites (because NKCC maintains ECl > Erest) and hyperpolarizes the axon terminal (because KCC2 maintains ECl < Erest).
The two transporters are expressed differently by horizontal cells
The expression of cation chloride cotransporters by horizontal cells was of special interest because ECl has been measured (see Discussion). We identified horizontal cells by immunostaining for parvalbumin (monkey; Röhrenbeck et al., 1987) or calbindin (rat and rabbit; Pasteels et al., 1990; Mitchell et al., 1995). Anti-KCC2 did not colocalize to any part of the cell (Fig.6). However, anti-NKCC (monkey, rat, and rabbit) did colocalize in somas and dendrites (Fig.7). These results, combined with the observation that anti-KCC2 and anti-NKCC applied together did not colocalize in the horizontal cell stratum suggest that horizontal cells express only NKCC (but see Vu et al., 2000). Curiously, the fine horizontal cell spines that invaginate the photoreceptor terminal did not express NKCC (Figs. 3, EM, 7). Thus, within the invagination of a photoreceptor terminal, all punctate stain for NKCC represents ON bipolar dendritic tips.
DISCUSSION
We feel confident that the staining patterns described here represent the actual expression of the two cation chloride cotransporters KCC2 and NKCC (Fig. 8). First, their amino acid sequences are well conserved across mammalian species, and recognition of these sequences by the present antibodies has been established in other tissues (Lytle et al., 1995; Williams et al., 1999). Second, in retina of three species, each antibody recognized a single protein band of the expected molecular weight, and the staining pattern for each antibody was nearly identical in up to seven mammalian species. Third, preabsorbtion with the immunizing peptide for KCC2 eliminated staining. Finally, both antibodies localized to the expected subcellular locus for these transporters i.e., the plasma membrane (Fig. 5). The NKCC antibody recognizes two isoforms, but one of these (NKCC2) is expressed only in kidney (Gamba et al., 1994; Payne and Forbush, 1994); therefore the isoform in retina is probably NKCC1.
Evidence that NKCC and KCC2 contribute to ECl
In most neurons, ECl is negative to Erest, so opening a chloride conductance causes Cl− influx and thus a hyperpolarizing postsynaptic potential (Eccles, 1964). Yet in certain neurons, ECl is positive to Erest, so opening a chloride conductance causes Cl− efflux and thus a depolarizing postsynaptic potential. Neurons with positive EClinclude the following: developing hippocampal pyramidal cells, suprachiasmatic neurons at day time, retinal horizontal cells, and Rhohon-Beard spinal neurons (Andersen et al., 1980; Bixby and Spitzer, 1982; Perlman and Normann, 1990; Kamermans and Werblin, 1992;Wagner et al., 1997).
Recent studies suggest that ECl can be maintained negative or positive to equilibrium (ECl ≠ Erest) primarily by two chloride transporters, NKCC and KCC2. For example, as hippocampal neurons mature and ECl switches from positive to negative relative to Erest, these neurons reduce expression of NKCC (Plotkin et al., 1997) and begin to express KCC2 (Lu et al., 1999; Rivera et al., 1999). Similarly, as retinal ganglion cells mature and switch their GABA responses from depolarizing to hyperpolarizing (Bahring et al., 1994; Huang and Redburn, 1996; Fischer et al., 1998), they begin to express KCC2 (Vu et al., 2000). Functionally, Rivera et al. (1999) demonstrated that antisense oligonucleotide inhibition of KCC2 expression in mature hippocampal pyramidal neurons produced a significant positive shift in the reversal potential of the GABAA response. Also, cultured midbrain neurons shift ECl from negative to positive when furosemide blocks K-Cl cotransporter (Jarolimek et al., 1999), and Rohon-Beard neurons shift ECl from positive to negative when bumetanide blocks Na-K-Cl cotransporter (Rohrbough and Spitzer, 1996). Although NKCC and KCC2 are likely the main neuronal Cl− transporters, there are other Cl− transporters that may contribute to Cl− homeostasis, including Na+-independent and Na+-dependent Cl−/HCO3−exchangers (Kaila, 1994) and certain Cl−channels (ClC-2) (Smith et al., 1995; Staley et al., 1996; Enz et al., 1999).
Here, testing for both transporters in multiple cell types of one region in adult brain has allowed two important conclusions. First, we obtained systematic evidence that the polarity of ECl correlates remarkably well with the cation chloride cotransporter that is expressed. For example, mature horizontal cells have a directly measured positive ECl and depolarize to GABA (Miller and Dacheux, 1983; Djamgoz and Laming, 1987; Perlman and Normann, 1990; Blanco et al., 1996); they express NKCC. ON bipolar dendrites should have positive ECl to explain the surround antagonism attributable to their GABAA receptors (Vardi and Sterling, 1994); they express NKCC. OFF bipolar dendrites and ganglion cells have a negative ECl and hyperpolarize to GABA (Miller and Dacheux, 1983; Wässle et al., 1986; Tachibana and Kaneko, 1987; Müller et al., 1992; Fischer et al., 1998); they express KCC2. Second, we obtained evidence that different regions of certain neurons express different cation chloride cotransporters, and this permits differential responses to GABA. In the rod bipolar cell, the axon terminal expresses KCC2 in which GABA hyperpolarizes, and the dendritic tip expresses NKCC in which GABA presumably depolarizes. Thus, it appears that these cotransporters can maintain a precisely regulated chloride gradient, quite remarkably even in a compact cell as the rod bipolar cell (∼100 μm long, ∼20 μm wide).
Intracellular chloride has rarely been measured directly but rather assessed by the polarity of voltage or current flow in response to activating a ligand-gated chloride conductance. Further direct measurements of intracellular chloride are needed, as well as the effects of blocking the transporters with appropriate concentrations of “loop” diuretics (Payne et al., 1995; Payne, 1997). However, even lacking these difficult measurements, one can reasonably conclude that the opposite effects of GABA on different neurons (or different parts of the same neuron) primarily depend on whether chloride is locally extruded or locally accumulated. More broadly, targeting specific transporters can be used to enhance the computational diversity of a particular transmitter–receptor pair.
Other possible functions of the Cl−cotransporters in bipolar cells
The differential distribution of NKCC and KCC2 in dendritic tips of ON and OFF bipolar cells supports our prediction that these two cell classes should exhibit opposite responses to GABA. However, it is conceivable that the depolarizing responses to GABA would exert a shunting inhibition and thus not contribute to the surround response. If this is the case, why would each cell type express a different Cl− cotransporter? In non-neuronal cells, the main function of the Na-K-Cl and K-Cl cotransporters (primarily NKCC1 and KCC1) is to regulate cell volume, and both cotransporters can conceivably contribute to regulation of extracellular K+. It is possible that the neuronal isoforms localized here to different subcellular compartments (NKCC1 and KCC2) also contribute to cation and water homeostasis. If so, ON and OFF bipolar classes may require different cotransporters because cation fluxes in these cells are inversely correlated; light closes cation channels in OFF bipolar cells and opens cation channels in ON bipolar cells.
Footnotes
This work was supported by National Institutes of Health Grants EY00828, EY11105, and NS36296. We thank Madeleine Johnson for her contributions to the early stages of this project, Sally Shrom and Dr. Jian Li for electron microscopy, and Sharron Fina for preparing this manuscript.
Correspondence should be addressed to Noga Vardi at the above address. E-mail: noga{at}retina.anatomy.upenn.edu.